|Publication number||US7552801 B2|
|Application number||US 11/235,883|
|Publication date||Jun 30, 2009|
|Filing date||Sep 27, 2005|
|Priority date||Sep 27, 2004|
|Also published as||US20060065492|
|Publication number||11235883, 235883, US 7552801 B2, US 7552801B2, US-B2-7552801, US7552801 B2, US7552801B2|
|Original Assignee||Electronics Micro Systems, Inc.|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (40), Referenced by (6), Classifications (11), Legal Events (4)|
|External Links: USPTO, USPTO Assignment, Espacenet|
The present application claims priority of U.S. Provisional Application Ser. No. 60/613,534 filed Sep. 27, 2004, and hereby incorporates herein by reference the same Provisional Application (including, but not limited to, “Appendix A” entitled “Lobby Intercom Display, Version 3”).
The present invention relates to display systems and methods having individually addressable monitor units. By way of example, these display systems and methods can be used to display advertisements and the like, and can include monitor units that are located, for example, within elevator cabs and/or within elevator lobbies.
Time spent by elevator passengers riding in an elevator cab and/or waiting within an elevator lobby for an elevator cab to arrive is typically wasted. During such circumstances, it is typical for such persons to feel awkward, and they accordingly may strive to avoid making eye contact with other passengers. Accordingly, there is a need for an improvement in elevator cabs and elevator lobbies that facilitates effective time usage by those persons riding in an elevator cab or waiting within an elevator lobby.
Accordingly, it is one aspect of the present invention to provide an improvement in elevator cabs and elevator lobbies that facilitates effective time usage by those persons riding in an elevator cab or waiting within an elevator lobby. To achieve the foregoing and other aspects, and in accordance with the purposes of the present invention defined herein, display systems and methods having individually addressable monitor units are disclosed.
For example, in one embodiment, a display system includes a plurality of monitor units, each of which has an enclosure that supports a display screen, a communication port, a power port, a storage device, and a control circuit. The control circuit is electrically connected with each of the display screen, the communication port, the power port, and the storage device. While the control circuit does not comprise a general purpose computer and is unable to operate an off-the-shelf operating system, it is selectively connected to a general purpose computer via a communications conduit. More particularly, the communications conduit is sequentially connected to the communication port of each monitor unit such that each monitor unit is individually addressable over the communications conduit to receive individualized control information and image information from the general purpose computer when connected thereto by the communications conduit. The control circuit of each monitor unit stores the control information and the image information within the storage device and acts in accordance with the stored control information to selectively provide the stored image information to the display screen.
In another embodiment, an elevator system is provided for movement of passengers among respective floors of a building. The elevator system has an elevator cab that is moveably supported within an elongated vertical passageway adjacent to a plurality of lobbies respective to each floor of the building. A control system is connected with the elevator cab and selectively moves the elevator cab through the passageway so that the elevator cab may drop off and receive passengers to and from the lobbies. A display system may be provided to the elevator system with monitor units of the display system disposed in locations visible to elevator passengers, such as inside of the elevator cab and in the lobbies. The monitor units may be sequentially connected among the floors of the building and into the elevator cab(s).
Further additional exemplary embodiments are contemplated that related to methods of displaying image information on a plurality of monitors units connected over a sequential arrangement. Image information and control information are provided to the monitor units by a general purpose computer via a communications conduit. The image information and control information are stored in the monitor units such that the image information is displayed by the monitor units in accordance with control information.
Accordingly, the present invention is advantageous for providing an improvement in elevator cabs and elevator lobbies that facilitates effective time usage by those persons riding in an elevator cab or waiting within an elevator lobby. Additional aspects, advantages, and novel features of the invention will be set forth in part in the description that follows, and in part will become apparent to those skilled in the art upon examination of the following, or may be learned with the practice of the invention. The aspects and advantages of the invention may be realized or attained by means of the instrumentalities and combinations as set forth herein and as will be apparent to those of ordinary skill in the art.
While the specification concludes with claims particularly pointing out and distinctly claiming the present invention, it is believed that the same will be better understood from the following description taken in conjunction with the accompanying drawings in which:
The present invention and its operation is hereinafter described in detail in connection with the views and examples of
In the embodiment of
Elevator cab 10 is shown to have a pushbutton panel 32 that is configured to receive floor selections and other input from passengers 20. Likewise, pushbutton panels 28 can be provided within each elevator lobby 14 and can be configured to enable prospective elevator passengers (e.g., 62) to call the elevator cab 10 to their floor location.
Referring now to
The external configuration of the monitor unit 26 is depicted in
In order to achieve the thinnest possible profile and overall smallest possible enclosure size, it will be appreciated that the components of the monitor unit are carefully selected to balance flexibility and functionality with size reduction. To achieve this result, the monitor unit 26 does not include a general purpose computer. A general purpose computer (e.g., a DOS- or Windows-based personal computer) is not desirable for implementation as a monitor unit in the present invention due to its relatively large physical size and its complexity as compared to that required of the monitor units described herein. Also, a general purpose computer, due to its complicated software and hardware architecture, can be considerably less reliable than a monitor unit described herein. Furthermore, because the monitor units described herein generally include less components than a general purpose computer, the price of a monitor unit can be significantly less than a general purpose computer. Also, because the monitor units involve fewer components than a general purpose computer, their power consumption is also generally lower. By not including a general purpose computer, a monitor unit in accordance with the teachings of the present invention might not be configured to interface with communications protocols which are typically native to general purpose computers such as, for example, Ethernet and TCP/IP. Further, it is contemplated that the monitor units generally do not comprise any viewer or passenger-accessible controls, such as pushbuttons or switches or, more particularly, a keyboard or mouse.
Control circuit 54 is also connected with a storage device 46. The storage device 46 can be configured to store image information (e.g., containing images for display upon the display screen 45). The storage device 46 might also be configured to store control information (e.g., for instructing the control circuit 54 as to which of the stored data images to display on the display screen 45 at any particular time). In one embodiment, the storage device 46 may comprise a receptacle along with a removable memory card. It will be appreciated that this removable memory card can assume any of a variety of formats, such as, for example, Smart Media, Memory Stick, Multimedia Card, Secure Digital, Compact Flash, and/or many others. Advantages of removable memory cards include ease of memory enhancement, ease of replacement of faulty memory, ease of data content replacement, and many others. Although both the image information and the control information may be stored on a removable memory card, in some embodiments, only the image information is stored on the removable memory card while the control information is stored in a separate (and possibly non-removable) storage device (e.g., BIOS memory) that is associated with the control circuit. Image information can be formatted and/or stored upon a removable memory card in a manner different than that which is familiar to a digital camera (i.e., so that a monitor unit could not extract image information from a memory card taken directly from a digital camera).
In other embodiments, no portion of the storage device 46 is removable (e.g., the entire storage device might be soldered in place). Advantages of non-removable memory include reduced cost, increased speed, increased reliability, and others. Although volatile memory may be employed, it will be appreciated that non-volatile memory will desirably be used in order that the image information is not lost if power to the power port 44 is interrupted.
A communications port 29 may also be provided, and may be connected with the control circuit 54. As will be described in further detail below, communications port 29 can be adapted to receive image information and/or control information from a remote source such as a general purpose computer. Any of a variety of data formats might be employed, as discussed in further detail below.
As shown in
It will be appreciated that a display system in accordance with the teachings of the present invention can include monitor units that are connected sequentially by a communications conduit 34, as shown for example in
It will be appreciated that a sequential connection among individual monitor units (e.g., as shown in
The monitor units of the present invention are configured to receive image information and control information over the communications conduit, and then to resultantly display the image information in accordance with instructions provided within the control information. The monitor units therefore are not configured to display image information in real time as the image information is received over the communications conduit (e.g., they are not configured like television sets receiving cable television signals). Furthermore, different image information and control information can be provided to respective monitor units within a display system in accordance with the teachings of the present invention. To provide such functionality, each monitor unit can be individually addressable upon the communications conduit. In one particular example, a two-wire RS-485 connection can be provided to connect multiple monitor units within a display system (e.g., as in
A connector 38 might also be provided at some point along the communications conduit 34. The connector 38 can be configured to selectively interface a general purpose computer 31, as shown for example in
One advantage of this system is that there is no need for a general purpose computer dedicated to the task of overseeing the monitor units. Rather, a laptop (a variety of general purpose computer) or other portable device may be connected to download new information to the monitor units only periodically (e.g., daily, weekly or monthly). As another advantage, because the information is not displayed on the monitor units in real time as it is transferred to the monitor unit, the data transfer speed need not be very high, and slower data transfer protocols (e.g., such as RS-485) can be effectively employed. These slower data transfer protocols are often simpler and less expensive to install and maintain than higher speed protocols that would be necessary to provide real time display of images as they are downloaded from a general purpose computer. Also, information need not ever be transmitted back from a monitor unit to the general purpose computer (although such reverse transmission may occur to enable the general purpose computer to verify that a monitor unit has received certain data).
To install a display system in accordance with the present invention, monitor units can be hung upon walls of elevator cabs and/or elevator lobbies of an elevator system. Power can be provided to each of the monitor units from any of a variety of power supplies that may be local to the individual monitor units. The communications conduit can be connected as discussed above. A general purpose computer may then be temporarily connected with the communications conduit. Through use of the general purpose computer, control information and image information can then be individually sent to each of the monitor units over the communications conduit. The image information can comprise images such as JPEG, TIFF, BMP, GIF, PNG or any of a variety of other data types. The control information can instruct the monitor units as to how to display the image information. For example, the control information can constitute a series of scripts, each of which can indicate an image to display and a length of time for display of that image. As the control circuit processes the control information, each of these scripts is acted upon in succession, thereby causing the desired sequence of images to be displayed on the display screen. The control information might also include additional information as well, such as specific aspects regarding the manner in which images shall be removed and/or placed upon the display (e.g., fade in/out).
In one specific example, a general purpose computer may be used to download image information to a monitor unit that includes eighty JPG images, as well as control information containing eighty script commands. Each image may be a separate advertisement, and the script commands may be written such that each image appears on the display screen for ten seconds, thereby enabling passengers sufficient time to view and absorb all of the information within each image. After all of the images have been displayed, the script commands repeat until new control information is downloaded from the general purpose computer. In an alternate example, the image information might include ninety images, but the scripts might cycle images fifteen times per second (or more frequently), thereby resulting in the appearance of a six second video on the display screen. It should be appreciated that virtually any combination of still images and video (i.e.: quickly sequenced still images) can be displayed upon a given monitor unit. A monitor unit might also be provided with a speaker in order that audio can be provided in connection with the images or in lieu of the images.
The progression of scripts may also be related to a motion sensor optionally provided within (or in close proximity to) a monitor unit. The motion sensor, generally electrically connected with the control circuit of a monitor unit and supported by the enclosure thereof, may be configured to generate activation signals such that the control circuit is operative to selectively display image information on the display screen of the monitor unit at least partially in response to the activation signals generated by the motion sensor. For example, if a motion sensor detects passengers, the script may be started such that images are displayed. In another embodiment, the motion sensor might merely control whether the backlight for the display screen is activated. Providing a motion sensor can thereby disable at least some components of a monitor unit when passengers are not present, thus conserving energy and extending the useful life of the monitor unit.
While images cannot be downloaded to and displayed by the monitor units in real time, control information (e.g., scripts) can be downloaded to a monitor unit in real time (i.e., nearly instantaneous, as compared to the time necessary for an elevator to move between floors). Control information, once received by a monitor unit, can cause an already stored image within the storage device of a monitor unit to be displayed in real time. Accordingly, the images presented on a monitor unit can be controlled in real time, provided that the images themselves had been previously stored in the local memory (e.g., the storage device) of the monitor unit. For example, if a building has ten floors (e.g., as in
Using the display systems and methods provided herein, it will be appreciated that passengers within an elevator cab and/or an elevator lobby can be presented with advertisements during their time waiting on or for an elevator cab. While the passengers may enjoy having these advertisements to occupy their waiting time, the building managers may profit by selling this advertising time to vendors. In the elevator system context, it should also be appreciated that the display system might be configured to display, either in addition to or in lieu of advertisements, information concerning weather, geographic aspects, elevator cab location information, product information, service information, and building occupant directory information, or any other information of interest to passengers.
The display systems and methods described herein may also be used in locations not involving elevator systems. For example, such a display system might be installed within a retail store, wherein individual monitor units are positioned at various locations around the store, such as near respective products being sold. Such monitor units could then provide dynamic information regarding those products. As another example, such a display system might be installed within a museum or other public exhibit, wherein individual monitor units can be placed near particular items or groupings of items within the exhibit. Information regarding those items or groupings can then be dynamically displayed upon the monitor units.
The monitor unit is a video image display device which can be based upon the “System on Chip” system. This principle can be applied in the monitor unit by the use of a Field Programmable Gate Array (“FPGA”). The FPGA might be the only programmable decision-making component within the monitor unit, and firmware within the FPGA can control the operation and the function of the entire monitor unit. Even though a monitor unit can be built using state of the art technology, the price of a monitor unit can be much lower than that of a general purpose computer. For example, a cost efficient monitor unit can include main memory comprising high capacity Synchronous Dynamic Random Access Memory (“SDRAM”) and buffer memory comprising small size static memory. The power consumption of a monitor unit (e.g., 8.4 W) can also be much lower than that of a general purpose computer (e.g., 100 W), thus resulting in a significantly reduced operating cost for the monitor unit. Maintenance costs of a monitor unit are also minimal as compared to a general purpose computer due to superior reliability of the monitor unit, reduced need for periodic service, and ability for remote software reconfiguration. A monitor unit can also be smaller than a general purpose computer as its size can be substantially limited to the physical size of its display screen. Monitor units can be placed in extremely varied locations such as entrances, hallways, elevators, and multi-screen applications (wherein several monitor units are assembled to obtain a larger screen).
A monitor unit in accordance with the present invention can include several components arranged in any of a variety of suitable configurations. For example, the components can be selected so that the monitor unit can operate within a desired temperature range (e.g., 5-45 degrees Celsius). Also, to optimize reliability, the monitor unit can be designed to have the smallest possible number of components and moving parts. The monitor unit can be provided with a 12 V.D.C. power supply, and components within the monitor unit can convert this supply voltage to other voltages as needed.
The monitor unit can include a display screen, such as an LCD display screen. An LCD display screen can provide a good quality image, high resolution and a small mounting size. LCD display screens generate less heat than other conventional screens, and associated electronic components can accordingly be closely disposed. As a result, monitor units incorporating an LCD display screen can be provided in small packages suitable for use in small spaces (e.g., in an elevator). A display screen can have six or eight color bits per pixel, although the difference in picture quality is not significant between these options, and a lower frequency can be used and less cost is involved when only six bits per color are used. Low Voltage Differential Signaling (“LVDS”) can be used as the communication standard between the display and the circuit board so that the video data can be sent through of a relatively small number of wires. The display screen can be provided with a digital interface so that the need for an analog/digital conversion is eliminated. Practically, of all components of the monitor unit, the display screen has the lowest Mean Time Between Failure (“MTBF”). Nevertheless, the MTBF standing of the monitor unit is high as compared to systems that involve a general purpose computer. The monitor unit can also include an inverter for powering a backlight for the display screen. The inverter provides a high voltage constant current power generator for the backlight of the display screen, and the use of a display screen refresh frequency ranging around the inverter frequency should be avoided.
A monitor unit can be connected directly to a general purpose computer through a Universal Serial Bus (“USB”) or can be connected to an RS485 bus. In particular, the monitor unit can include a USB connector and can operate as a slave on a USB bus. An interface chip facilitates conversion between the USB and Low Voltage Transistor to Transistor Logic (“LVTTL”) signals. Communication between the interface chip and the FPGA is done by Universal Asynchronous Receive Transmit (“UART”). The communication rate ranges between 9600 bps and 3 Mbps and is set by software within the USB-Master device (e.g., a general purpose computer). The USB chip can be line-powered so that there is no need for a separate power source. An Electrically Erasable Read Only Memory (“EEprom”) and/or a crystal can also be provided.
The monitor unit can include a connector for interfacing an RS485 bus and can be placed upon the RS485 bus as a passive device. Passive operation means that the monitor unit cannot send packages on the bus of its own will. The available baud rate depends upon such factors as the length and type of the RS485 cable and the type of line transceiver used. The longer the cable, the lower the maximum baud rate that can be used. The RS485 interface used can be the dominant or standard RS485 mode. A server (e.g., a general purpose computer) may send various types of data packages and commands packages over the RS485 bus to the monitor unit. The monitor unit can receive these packages from the bus according to a certain protocol, and can issue messages confirming receipt of certain packages. Data packages can transfer a file from the monitor unit to the server according to a TCP/IP transfer mechanism.
The monitor unit can additionally include a circuit board which can provide, support or otherwise interface some or all of the other components of the monitor unit. The circuit board can be capable of high frequency (e.g., 7MHz-80MHz) operation. Components can be mounted on one or both sides of the circuit board, and the circuit board may have one or more layers. For example, the circuit board can include components for interfacing the display screen such as a LVDS transceiver and related connectors. Cables can be provided within the monitor unit to connect together the various components of the monitor unit.
A monitor unit can also include many software elements such as, for example, an SDRAM controller, a Joint Photographic Expert Group (“JPEG”) decoder, a UART, a Compact Flash (“CF”) interface, a Static Random Access Memory (“SRAM”) interface, a display screen controller, a processor, a Serial Peripheral Interface (“SPI”), and/or an Integrated Drive Electronics (“IDE”) interface. A Timer interface can also be provided to facilitate accurate measurement of time periods, and a Pixel interface can be provided to modify data in the SDRAM memory.
SDRAM memory (e.g., 128Mb) can be used to store decompressed images for display. Several (e.g., four) equally sized areas can be provided within the SDRAM which are each of sufficient size to hold a respective image. While an image is built in one of these areas, an already decompressed image in another area can be displayed on the display screen. Due to the high operation frequency, terminator resistors can be provided to prevent reflections from appearing due to the similar dimension of the wavelength and the course length. An SDRAM controller can be provided to interface the SDRAM with other components of the monitor unit. A display screen refresh can occur at the same time as a new image is being written in one of the areas. For example, twenty frames per second may be obtainable for a given resolution. An initialization macro command can prepare the SDRAM for subsequent operations and initializes the operating parameters for the SDRAM. A First In First Out (“FIFO”) data queue can store the data that are transferred between the SDRAM and the video controller and between the SDRAM and the JPEG block. After the initialization sequence, the display screen controller can command data reading and indicate refresh intervals. The SDRAM controller writes data for the video controller in FIFO at a constant speed with small breaks due to the additional line-closing/opening operations, and the video block reads the data at the same constant speed, but without breaks. The video block performs the LCD refresh and commands SDRAM refresh.
A monitor unit can include a CF card and/or Dataflash. A CF card can serve as the main non-volatile memory and can store serially received or pre-recorded files containing images and various operation and configuration information. Such files can be processed for display or they can be sent to other monitor units. A connector for receiving a CF card can be placed on the circuit board. Although a hard drive can be provided instead of a CF card to store data, the MTBF is low for a hard drive as compared to that of the CF card. A CF card has several access modes, namely I/O mode, memory mode, and true IDE mode. An IDE interface in the monitor unit enables the processor to communicate by implementing read and write access functions. Dataflash memory (e.g., 128 Mb) stores the processor program. An SPI interface can be used to communicating with Dataflash. Half of the memory contains the processor code, whereas the other half contains a start image.
Depending upon the hardware selected, there are several software configurations that can be provided within a monitor unit. The simplest hardware solution does not contain CF or serial Dataflash. The processor can decode communications (e.g., via USB or RS485) and JPEG file markers. No start image can be displayed, but rather a black screen can be displayed until the first picture is received. The serial data received can be stored in SRAM, and then the JPEG decoding can be done. SRAM memory can store remote data and the processor program data. Half of the memory can serve as a buffer for JPEG images received serially, whereas the other half can be used by the processor as data and code memory. The UART block receives the serial data and the processor interprets them. The JPEG decoder receives data from the processor, decodes the image and stores the decoded image in SDRAM. The decompressed image can then be stored in SDRAM and displayed on the display screen. The FPGA can perform these operations. The video controller provides the display screen with the necessary data and timing. The screen can display a welcome string, and can then display a digital clock and an analog clock. The monitor unit can wait for JPEG files to be received in full before displaying them.
In an alternate configuration, a monitor unit contains a CF card or Dataflash. There are two software solutions. The first solution does not require CF card, rather the processor boots from serial DataFlash and displays a start image stored in DataFlash. The monitor unit may receive JPEG files and can display them. The second solution does not require DataFlash. Rather, the processor boots from CF, then executes a script, according to which it can receive serial files, transmit serial files, read or write files in CF and display on the screen any JPEG file received serially or stored on CF. Accordingly, the monitor unit can receive static image compressed files in a JPEG format from the CF card and displays them on the display screen. Alternatively, pictures displayed on the screen can be received from an RS485 communication bus, from a server, or from another monitor unit.
The JPEG decoder operates by first decoding the structure of the received data. The processor is in charge of this step, and can program the currently displayed buffer and the decoding buffer. To decode an image, a decoding buffer can be selected and then a file must be transferred to the decoder. The processor identifies markers in the JPEG baseline such as SOS (start of scan), SOF (start of file), DHT (decoder huffman table), DQT (decoder quantization table), and EOF (end of file). Upon receipt of a header, the processor sends the data in each marker body to the decoder. The processor does not allow for the decoding of a file with an incomplete or wrong format header. While receiving data, the header block decodes the data and generates necessary tables based on the information received. After reception is over, the data is read from RAM to generate the uncompressed picture. The picture can be processed block by block by Huffman decoding, dequantization and zigzag ordering, and then by Inverse Discrete Cosine Transformation (“IDCT”).
The monitor unit can include a processor (e.g., a RISC processor) which functions to support various communications protocols, read/write data, process images, facilitate display of text, and facilitate automatic testing and diagnostics. The processor can be selected to have a small physical size. Upon turning on the monitor unit, the processor performs the functional testing of the main components (integrity, memory, stored data, CRC, etc.) and can also facilitate display of a logo image. The processor can transmit and receive data through use of a UART Interface. The processor executes code from the boot zone (internal ram in the FPGA) and from external static memory. The boot code performs minimal functioning tests, and then copies the code and initialized variables from the Dataflash or CF memory into the external memory. The boot zone may be extended depending on the ram available in FPGA. If the program does not need a code larger than the boot zone, the external ram is not necessary. The main code can be run from the external static memory. To avoid collisions between data, a memory map can be defined.
When the monitor unit is assembled and powered, the firmware starts execution. In the first stage, characters are transmitted through the RS485 or USB to confirm operation of the monitor unit. Existence of the serial flash is then verified and if missing, the processor stops. Then, testing of the external ram is started. In case of an error, the address where the error was found is read. If the test is successfully passed, the minimal functions are deemed operational and the boot mode confirmation is expected. If no character is serially received for two minutes, the processor tries to boot from the Dataflash. If the Dataflash is corrupted or was not programmed, the processor continues to wait for the confirmation of a boot mode. Otherwise, the processor copies the Dataflash code into SRAM and executes it. After the program is received, the processor calls a program writing sub-routine in flash that can be found in the received object code. After the writing, the received object code is executed. After the serial flash code is copied into SRAM, it starts to execute the main code. At this time, the CF presence is keyed in. The processor reads the CF identification data and if the CF is present, it displays them. If a CF card is not detected, the processor stops.
The main program can perform several functions, namely a terminal mode, a script mode, and an RS485 mode. In every mode, the operation is completely different. In the terminal mode, the commands are manually introduced and are executed after they are introduced. In the script mode, the commands are similar to the terminal mode, but they are stored in memory and successively executed, without any pause between them. The RS485 mode operates differently.
Generally, the program commands execution of the script. A script represents a series of strings defined in memory. The commands in script are interpreted by the monitor unit. A “stor” command can be used to select and write into memory one of the images from a CF card. The “play” command distributes one of the CF files to another device on an RS485 bus. The “decf” command orders the decoding of a JPEG file. The “decb” and “view” display an image stored in one of the four JPEG buffers. The “simp” command orders execution of the script from the desired position and may be executed both the terminal and script modes. In the script mode, this function may be used to obtain an infinite script. The “m485” command orders the shift of the monitor unit into the RS485 mode. The “pstr” command performs a series of graphic functions. The “bcst” command cannot be interrupted. The “stmv” command stores in CF a sequence of multiple JPEG files and can only be used in terminal mode. The “plmv” command displays the stored image sequence. The script is completed when a “kill” command is detected.
Command packages include a “show file”, a “new program”, and a “store file”. The “show file” command package determines which file is displayed on the display screen. If the file was not received, the command will not do anything. The “new program” command package replaces a program stored in Dataflash with a new program previously sent on the serial link. The “store file” command package replaces or adds a file in CF. If the file was not sent or if it suffered an error, the command has no effect. The command has as a parameter the number of the location where the file has to be saved. Multiple data protection mechanisms may also be provided. For example, sequential number data protection can be used to protect against package losses, start/stop package data protection can also be used to ensure that an entire file is sent, and CRC16 CCITT can be used to detect common errors (e.g., bit errors, odd burst errors).
A monitor unit interprets the package if the address on the package corresponds to its address, or if the address on the package is a broadcast address. The packages that have a different address are ignored. If a package is lost while transferring a file, the entire file can be resent. The commands receive a response package that confirms or rejects the execution. The monitor unit can then send a package indicating error or success.
The foregoing description of embodiments and examples of the invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the forms described. Numerous modifications are possible in light of the above teachings. Some of those modifications have been discussed and others will be understood by those skilled in the art. The embodiments were chosen and described in order to best illustrate the principles of the invention and various embodiments as are suited to the particular use contemplated. The scope of the invention is, of course, not limited to the examples or embodiments set forth herein, but can be employed in any number of applications and equivalent devices by those of ordinary skill in the art. Rather it is hereby intended the scope of the invention be defined by the claims appended hereto.
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|U.S. Classification||187/391, 187/396|
|Cooperative Classification||B66B1/3415, B66B3/00, B66B3/008, B66B1/34|
|European Classification||B66B3/00B6, B66B1/34B, B66B3/00, B66B1/34|
|Nov 28, 2005||AS||Assignment|
Owner name: ELECTRONIC MICRO SYSTEMS, INC., NEW YORK
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNOR:TRIFU, VICTOR;REEL/FRAME:017074/0042
Effective date: 20051116
|Feb 11, 2013||REMI||Maintenance fee reminder mailed|
|Jun 30, 2013||LAPS||Lapse for failure to pay maintenance fees|
|Aug 20, 2013||FP||Expired due to failure to pay maintenance fee|
Effective date: 20130630